站立前屈位X线片联合仰卧位MRI评估退变性腰椎滑脱节段的稳定性

目的:探讨站立前屈位X线片联合仰卧位MRI评估退变性腰椎滑脱节段稳定性的可靠性及可行性.方法:回顾性分析2016年1月1日~2018年6月30日在山东大学齐鲁医院(青岛)脊柱外科住院治疗的87例退变性腰椎滑脱症患者的临床资料.男20例,女67例;年龄47~87岁(65.9±9.0岁).滑脱节段:L310例,L466例,LS11例;依据Meyerding分类,Ⅰ度滑脱82例,Ⅱ度滑脱5例.所有患者均在站立位获得前屈、后伸侧位X线片及仰卧位MRI片,利用图像存档通信系统(PACS系统)对影像数据进行回顾性分析,包括站立位前屈(F)、后伸(E)X线片和仰卧位MRI(S),MRI图像选取T1加权正中矢状面图像.将滑脱距离与椎体宽度的百分比定义为滑脱百分比并用于最后分析.计算出F与E、F与S之间滑脱百分比的差值定义为滑移率.滑移率≥8%定义为节段不稳定.结果:三种体位平均滑脱百分比F位最大[(16.97±5.93)%],其后依次为E位[(14.04±6.38)%]和S位[(9.89±5.34)%],三种体位之间有统计学差异(F-E:P<0.01;F-S:P=0.00;E-S:P=0.00).F-S、F-E之间平均滑移率分别为(7.08±4.60)%(-0.49%~24.32%)、(2.93±3.29)%(-3.46%~11.24%),两者之间有统计学差异(P=0.00).以滑移率≥8%为标准,诊断为节段不稳的患者共40例,其中F-S发现37例(92.5%),F-E发现7例(17.5%);F-E显示滑脱节段不稳的7例中,4例F-S也显示不稳,另3例(7.5%)F-S未显示不稳.结论:对于退变性腰椎滑脱节段稳定性的评估,应用站立前屈侧位X线片结合平卧位MRI比站立前屈后伸位X线片能更好地显示滑脱节段的不稳定;站立前屈位X线片联合仰卧位MRI片可明显提高诊断的准确性,降低漏诊率.

过伸过屈位MRI评估脊髓型颈椎病退变临近节段功能

目的使用过伸过屈位MRI评估脊髓型颈椎病严重退变节段临近节段稳定性及脊髓压迫程度的动态改变,为评估病情提供参考。方法选取2014年7月—2016年7月哈尔滨医科大学附属第一医院确诊为脊髓型颈椎病且中立矢状位MRI表现为Muhle分级2级以上的的患者95例,按照脊髓压迫所在最重节段分为C3/C4(16例),C4/C5(27例),C5/C6(34例),C6/C7(18例)4组,再按照脊髓压迫严重程度将病例分为2级组(31例),3级组(64例)均加拍过伸过屈位MRI片,并于所成MRI的T2矢状位下,以脊髓压迫加重病例数衡量评估退变节段头尾端节段脊髓压迫状态的动态变化,测量过伸过屈位下退变最严重节段临近头尾端各一个节段的椎间角位移,颈椎总体的角度位移,所测得角位移之和反映相应节段及颈椎总体活动功能,对于其节段稳定性及脊髓压迫程度的动态变化进行分析。结果颈椎总体活动度为(28.31±4.66)°,(35.29±3.65)°,(32.81±4.43)°,(27.08±5.64)°,该节段活动度为(9.96±5.78)°,(11.58±4.43)°,(7.08±2.69)°,(9.25±2.04)°,临近头端节段活动度为(3.16±2.16)°,(8.41±4.98)°,(10.98±2.44)°,(5.53±3.25)°,临近尾端节段活动度为(5.31±3.62)°,(4.08±3.28)°,(8.52±2.04)°,(2.15±3.44)°,其中颈椎总体活动度各组间差异无统计学意义,C5/6的本节段活动度,临近头端节段活动度以及临近尾端节段活动度同C3/4,C4/5以及C5/6组间差异均有统计学意义(P<0.05)。各组上下节段压迫提升率同相应节段活动度间缺乏相关性。结论过伸过屈位MRI可用于脊髓型颈椎病明显退变节段临近节段功能的评估,严重退变所在节段同临近节段功能变化有关,C5/6节段在颈椎临近节段退变过程中有重要意义。过伸过屈位MRI可用于脊髓型颈椎病明显退变节段临近节段功能的评估,严重退变所在节段同临近节段功能变化有关,C5/6节段在颈椎临近节段退变过程中有重要意义。

Effect of lumbar angular motion on central canal diameter： positional MRI study in 491 cases

Background Lumbar spinal stenosis is a common problem that is receiving attention with the advent of novel treatment procedures. Prior positional MRI studies demonstrated lumbar canal diameter changes with flexion and extension. There have not been any studies to examine the amount of spinal canal diameter change relative to the amount of angular motion. The purpose of this study was to evaluate the correlation between the lumbar canal diameter change and the angular motion quantitatively. Methods Positional MRI （pMRI） images for 491 patients, including 310 males and 181 females （16 years-85 years of age）, were obtained with the subjects in sitting flexion 40 degree, upright, and with extension of 10 degrees within a 0.6 T Positional MRI scanner. Quantitative measurements of the canal diameter and segmental angle of each level in the sagittal midline plane were obtained for each position. Then the diameter change and angular motion were examined for correlation during flexion and extension with linear regression analysis. Results The lumbar segmental angles were lordotic in all positions except L1-2 in flexion. The changes of canal diameters were statistically correlated with the segmental angular motions during flexion and extension （P 〈0.001）. The amount of canal diameter change correlated with the amount of angular change and was expressed as a ratio. Conclusions Positional MRI demonstrated the amount of spinal canal diameter change that was statistically correlated with the segmental angular motion of the spine during flexion and extension. These results may be used to predict the extent of canal diameter change when interspinous devices or positional changes are used to treat spinal stenosis and the amount of increased canal space may be predicted with the amount of angular or positional change of the spine. This may correlate with symptomatic relief and allow for improved success in the treatment of spinal stenosis.